von Willebrand factor is a cofactor for thrombin-catalyzed cleavage of the factor VIII light chain

The proteolytic activation of highly purified, heterodimeric porcine factor VIII and factor VIII-von Willebrand factor complex by thrombin was compared at I 0.17, pH 7.0, 22 degrees C. During the activation of factor VIII, heavy-chain cleavage is necessary to activate the procoagulant function, whereas light-chain cleavage is required to dissociate factor VIII from von Willebrand factor. The kinetics of activation of free factor VIII and factor VIII-von Willebrand factor complex were identical. The steady-state kinetics of thrombin-catalyzed heavy-chain cleavages and light-chain cleavage of factor VIII either free or in complex with von Willebrand factor were studied using sodium dodecyl sulfate-polyacrylamide gel radioelectrophoresis and scanning densitometry of fragments derived from 125I-labeled factor VIII. Association of factor VIII with von Willebrand factor resulted in an 8-fold increase in the catalytic efficiency (kcat/Km) of light-chain cleavage (from 7 x 10(6) to 54 x 10(6) M-1 s-1). The catalytic efficiencies of heavy-chain cleavage at position 372 (approximately 6 x 10(6) M-1 s-1) and position 740 (approximately 100 x 10(6) M-1 s-1) were not affected by von Willebrand factor. We conclude that von Willebrand factor promotes cleavage of the factor VIII light chain by thrombin which is followed by rapid dissociation of the complex, so that the rate-limiting step becomes heavy-chain cleavage at position 372. This accounts for the observation that von Willebrand factor has no effect on the kinetics of activation of factor VIII by thrombin.     

Binding of human factor VIII to phospholipid vesicles

Factor VIII, a protein cofactor involved in blood coagulation, functions in vitro on a phospholipid membrane surface to greatly increase the rate of factor X activation by factor IXa. Using gel filtration, rapid sedimentation, and resonance energy transfer we have studied the interaction of recombinant-derived human factor VIII with small and large unilamellar phospholipid vesicles composed of phosphatidylserine and phosphatidylcholine. Resonance energy transfer, from intrinsic fluorophores in factor VIII to dansyl-phosphatidylethanolamine incorporated into vesicles, has been adapted for quantitative equilibrium measurements. Factor VIII binds rapidly and reversibly to small and large vesicles. At 8 degrees C the interaction of factor VIII with small vesicles fits a simple bimolecular model with a KD of 2 nM and a phospholipid binding site defined by 180 phospholipid monomers. At 25 degrees C the binding of factor VIII to small vesicles containing 20% phosphatidylserine can be described by an apparent KD of 4 nM; the phospholipid/protein ratio at saturation was 170. Binding to large vesicles was demonstrated with a KD of 2 nM and a phospholipid/protein ratio at saturation of 385. Binding was dependent upon the phosphatidylserine mole fraction and was nonlinear from 0 to 30% phosphatidylserine content. A direct comparison of factor VIII and factor V binding indicated that the affinity of factor V to phospholipid vesicles was equivalent to that of factor VIII and that the phosphatidylserine requirement was lower. A model is proposed to explain the nonlinear phosphatidylserine dependence of binding for factor VIII.     

Thrombin-activated and factor Xa-activated human factor VIII: differences in cofactor activity and decay rate.

The decay of human coagulation factor VIIIa has been studied by kinetic methods that ensure no interference through proteolytic feedback. The rate of decay of factor VIIIa activity was found to vary with the activator used to activate factor VIII. Thrombin-activated factor VIII-von Willebrand factor complex (fVIII-vWf) decayed at a rate of 0.31 min-1, whereas factor Xa-activated fVIII-vWf decayed at 0.11 min-1 under the same conditions. Factor VIII free of von Willebrand factor (factor VIII: C), although decaying at a generally slower rate after activation, still showed a dependence of decay rate on activator: thrombin-activated factor VIII:C decaying at a rate of 0.06 min-1, and factor Xa-activated factor VIII: C at 0.01 min-1. Readdition of von Willebrand factor (18 micrograms/ml) to factor VIII:C did not alter the observed activity or decay rate. The decay of the two species of factor VIIIa was studied, using the fVIIIa-vWf complex, in the presence of varying levels of factor IXa. Plots of reciprocal decay rates vs factor IXa concentration were linear, and nearly parallel for the two factor VIIIa species, with a mean slope of 0.56 min.nM-1. In addition to these studies, we have confirmed previous studies showing that the two forms of factor VIIIa differ in cofactor activity, but they do so in the same ratio as in their decay rates. We suggest that this difference and that observed in decay rate have a common cause, and incorporate this into a potential kinetic model of factor VIII activation and decay.     

Factor VIII/von Willebrand Factor has potent lectin activity

Highly-purified plasma and platelet Factor VIII/von Willebrand Factor had potent lectin activity when measured in a haemagglutination assay. This lectin activity was inhibited by monoclonal and heterologous antibodies to Factor VIII/von Willebrand Factor as well as by hexosamines, mannose and net-positively charged amino acids.     

von Willebrand factor mediates protection of factor VIII from activated protein C-catalyzed inactivation.

Factor VIII, a cofactor of the intrinsic clotting pathway, is proteolytically inactivated by the vitamin K-dependent serine protease, activated protein C in a reaction requiring Ca2+ and a phospholipid surface. Factor VIII was inactivated 15 times faster than factor VIII in complex with either von Willebrand factor (vWf) or the large homodimeric fragment, SPIII (vWf residues 1-1365). Free factor VIII or factor VIII in complex with a smaller fragment, SPIII-T4 (vWf residues 1-272), were inactivated at the same rate, suggesting that this effect was dependent upon the size of factor VIII-vWf complex rather than changes in factor VIII brought about by occupancy of the vWf-binding site. Thrombin cleavage of the factor VIII light chain to remove the vWf-binding site eliminated the protective effects of vWf. In the absence of phospholipid, high levels of the protease inactivated both free and vWf-bound factor VIII at equivalent rates. Using the same conditions, isolated heavy chains and the heavy chains of factor VIII were proteolyzed at similar rates. Taken together, these results suggested that, in the absence of phospholipid, inactivation of factor VIII is independent of factor VIII light chain and further suggest that vWf did not mask susceptible cleavage sites in the cofactor. Solution studies employing fluorescence energy transfer using coumarin-labeled factor VIII (fluorescence donor) and synthetic phospholipid vesicles labeled with octadecyl rhodamine (fluorescence acceptor) indicated saturable binding and equivalent extents of donor fluorescence quenching for factor VIII alone or when complexed with SPIII-T4. However, complexing of factor VIII with either vWf or SPIII eliminated its binding to the phospholipid. Since a phospholipid surface is required for efficient catalysis by the protease, these results suggest that vWf protects factor VIII by inhibiting cofactor-phospholipid interactions.     

Specificity of phosphatidylserine-containing membrane binding sites for factor VIII. Studies with model membranes supported by glass microspheres (lipospheres).

Factor VIII functions in an enzyme complex upon the activated platelet membrane where phosphatidylserine exposure correlates with expression of receptors for factor VIII. To evaluate the specificity of phosphatidylserine-containing membrane binding sites for factor VIII, we have developed a novel membrane model in which phospholipid bilayers are supported by glass microspheres (lipospheres). The binding of fluorescein-labeled factor VIII to lipospheres with membranes of 15% phosphatidylserine was equivalent to binding to phospholipid vesicles (KD = 4.8 nM). Purified von Willebrand factor (vWf), a carrier protein for factor VIII, decreased membrane binding of factor VIII with a Ki of 10 micrograms/ml. Likewise, normal plasma decreased bound factor VIII by more than 90% whereas plasma lacking vWf decreased the binding of factor VIII by only 20%. Proteolytic activation of factor VIII by thrombin, which releases factor VIII from vWf, increased liposphere binding in the presence of vWf and in the presence of normal plasma. Although factor V is homologous to factor VIII and binds to lipospheres with the same affinity, purified factor V was not an efficient competitor for the membrane binding sites of factor VIII. These results indicate that phosphatidylserine-containing membrane sites have sufficient specificity to select thrombin-activated factor VIII from the range of phospholipid-binding proteins in plasma.     

Platelet-derived microparticles express high affinity receptors for factor VIII.

Factor VIII is a cofactor in the tenase enzyme complex which assembles on the membrane of activated platelets. A critical step in tenase assembly is membrane binding of factor VIII. Platelet membrane factor VIII-binding sites were characterized by flow cytometry using either fluorescein maleimide-labeled recombinant factor VIII or a fluorescein-labeled monoclonal antibody against factor VIII. Following activation by thrombin, most platelets bound factor VIII within 90 s. In addition, over the course of several minutes, membranous vesicles (microparticles) were shed from the platelet plasma membrane and each microparticle bound as much factor VIII as a stimulated platelet. Over 30 min, stimulated platelets (but not microparticles) lost the capacity to bind factor VIII. Factor VIII bound saturably to microparticles from platelets stimulated with thrombin, thrombin plus collagen, or the complement proteins C5b-9. The binding of factor VIII was compared to factor V, a structurally homologous coagulation cofactor. Analysis of microparticle binding kinetics yielded similar on and off rates for factor VIII and factor Va and KD values of 2-10 nM. In the presence of 20 nM factor Va, the binding of factor VIII to microparticles was increased, and there was a comparable increase in platelet tenase activity. At higher factor Va concentrations, factor VIII binding and tenase activity were inhibited. Conversely, factor VIII had a similar dose-dependent effect on factor Va binding and platelet prothrombinase activity. Synthetic phospholipid vesicles containing phosphatidylserine competed with microparticles for binding of factor VIII and factor Va. These studies indicate that activated platelets express a transient increase in high affinity receptors for factor VIII, whereas platelet-derived microparticles express a sustained increase in receptors. The binding characteristics of platelet membrane receptors for factor VIII are similar to those for factor Va.     

Von Willebrand-Jürgens syndrome with a variant of factor VIII-associated antigen]

A family is described in which 5 out of 8 children had a marked bleeding disorder. The children showed prolonged bleeding times, abnormal platelet retention upon passage of blood through a glass bead column, the Willebrand factor activity as measured by ristocetin in a washed platelet system was low. Factor VIII/von Willebrand factor protein levels were normal even so the factor VIII-procoagulant activity. Even the parents and one child without any bleeding tendency and normal bleeding times had a reduced Willebrand factor activity. In all these patients evidence of an abnormal protein was observed on crossed antigen-antibody electrophoresis indicating a qualitative defect of the factor VIII/von Willebrand factor protein.     

Stoichiometry of the porcine factor VIII-von Willebrand factor association

Factor VIII and von Willebrand factor (vWF) are glycoproteins that form a tightly bound complex in plasma. The interaction of porcine factor VIII with porcine vWF was studied by analytical velocity sedimentation. A single approximately 240-kDa species of factor VIII was isolated for use in the analysis. In contrast, when analyzed by agarose/sodium dodecyl sulfate-polyacrylamide gel electrophoresis, vWF consisted of a population of greater than 10 multimers derived from a 270-kDa monomer. A single boundary (So20,w = 7.2 S) was observed during velocity sedimentation of factor VIII at 260,000 x g. A single boundary also was observed for vWF (weight-average So20,w = 21 S) at 42,000 x g. Under condition of excess factor VIII, the weight-average So20,w of the factor VIII-vWF complex was 40 S at 42,000 x g. At 260,000 x g, the factor VIII-vWF complex had sedimented completely, leaving only free factor VIII. The height of the plateau region of the factor VIII sedimentation velocity curve at 260,000 x g was studied as a function of several starting concentrations of vWF. The experiments were done under conditions in which the effect of radial dilution was negligible so that the plateau height was a measure of the concentration of free factor VIII. The plateau height decreased linearly as the concentration of vWF was increased, indicating that the association was essentially irreversible under the conditions used. A stoichiometry of 1.2 vWF monomers/factor VIII molecule was calculated from the slope of the line. Assuming one factor VIII-binding site/vWF monomer, these results indicate that all factor VIII-binding sites are accessible in the vWF multimer.     

The interaction of bone Gla protein (osteocalcin) with phospholipid vesicles

The binding interaction of bone Gla protein (BGP), or osteocalcin, to phospholipid vesicles in the presence of calcium has been investigated. Two separate indirect methodologies involving displacement of pyrene-modified Factor Va bound to phospholipid vesicles, and competition with several coagulation proteins in a prothrombin activation assay were performed. Titration of BGP into a cuvette containing phospholipid vesicles (75:25, L-alpha-phosphatidylcholine/L-alpha-phosphatidylserine (PCPS] saturated with pyrene-modified Factor Va resulted in a systematic decrease in steady-state anisotropy, suggesting competition for membrane binding sites with pyrene-modified Factor Va. BGP was also found to inhibit thrombin generation in the prothrombin activation assay. Approximately 50% inhibition was observed at 3 microM BGP under phospholipid-limiting (0.5 microM PCPS) concentrations. No inhibition was observed under phospholipid excess (30 microM PCPS) concentrations. Direct measurement of phospholipid binding was measured using equilibrium gel filtration. Elution profiles using fixed lipid (3.4 mumol of PCPS) and varying BGP concentrations (1-17 microM) in the presence of 3 mM CaCl2 showed a BGP-phospholipid association. Quantitation of determined isotherm yielded a dissociation constant of 6 +/- 1 microM with a stoichiometry of 102 +/- 9 BGP molecules/vesicle at saturation (35 PCPS lipids/BGP) in the presence of 3 mM CaCl2. These results support the hypothesis that protein gamma-carboxylation events are coincident with membrane binding potential.     

The effect of plasma von Willebrand factor on the binding of human factor VIII to thrombin-activated human platelets

The binding of 35S-labeled recombinant human Factor VIII to activated human platelets was studied in the presence and absence of exogenous plasma von Willebrand factor. In the absence of added von Willebrand Factor, platelets bound 210 molecules of Factor VIII/platelet when the unbound Factor VIII concentration was 2.0 nM (Kd = 2.9 nM). As the von Willebrand factor concentration was increased, the number of Factor VIII molecules bound/platelet decreased to 10 molecules of Factor VIII bound/platelet at 24 micrograms/ml of added vWF. Addition of an anti-vWF monoclonal antibody that inhibits the vWF-Factor VIII interaction attenuated the ability of vWF to inhibit binding of Factor VIII to platelets. In contrast, addition of a control anti-vWF antibody that does not block the vWF-Factor VIII interaction did not affect the ability of vWF to inhibit Factor VIII binding to platelets. From the vWF concentration dependence of inhibition of Factor VIII-platelet binding, a dissociation constant for the Factor VIII-vWF interaction was calculated (Kd = 0.44 nM). To further elucidate the role that vWF may play in preventing the interaction of Factor VIII with platelets, the platelet binding properties of a Factor VIII deletion mutant (90-73) which lacks the primary vWF-binding site was studied. The binding of this mutant was unaffected by added exogenous vWF. These observations demonstrate that Factor VIII can interact with platelets in a manner independent of vWF but that excess vWF in plasma can effectively compete with platelets for the binding of Factor VIII. In addition, since cleavage of Factor VIII by thrombin separates a vWF-binding domain from Factor VIIIa, we propose that activation of Factor VIII by thrombin may elicit release of activated Factor VIII from vWF and thereby make it fully available for platelet binding.     

Human factor VIII procoagulant activity and phospholipid interaction

The interaction between purified human factor VIII and phospholipid vesicles was investigated. The binding of factor VIII to an equimolecular mixture of phosphatidylserine (PS) and phosphatidylcholine (PC) was studied by sucrose gradient ultracentrifugation (10–40% w/v saccharose in 0.01 M Tris-HCl/0.15 M NaCl buffer (pH 7). In the absence of phospholipids all factor VIII activities (VIII : C, VIII R : WF and VIII R : AG) were found in the zone of highest sucrose density including the factor VIII related protein subunit (200 000 molecular weight). In the presence of an equimolecular mixture of PS/PC VIII R : WF activity, VIII R : AG and a factor VIII related protein still migrated to the bottom of the tube, while VIII : C activity remained at the top where phospholipids were found. Thus a dissociation phenomenon between VIII : C and the other factor VIII relateda activities was apparent in the presence of phospholipids. These results also demonstrate the binding of factor VIII : C to certain active phospholipids.     

The contribution of bovine Factor V and Factor Va to the activity of prothrombinase.

The rates of prothrombin activation under initial conditions of invariant concentrations of prothrombin and Factor Xa were studied in the presence of various combinations of Ca2+, homogeneous bovine Factor V, Factor Va, phosphatidylcholine-phosphatidylserine vesicles, and activated bovine platelets. Reactions were monitored continuously through the enhanced fluorescence accompanying the interaction of newly formed thrombin with dansylarginine-N-(3-ethyl-1,5-pentanediyl) amide. The complete prothrombinase (Factor Xa, Ca2+, phospholipid, and Factor Va) behaved as a "typical" enzyme and catalyzed the activation of prothrombin with an apparent Vmax of 2100 mol of thrombin/min/mol of Factor Va or Factor Xa, whichever was the rate-limiting component. Regardless of whether the enzymatic complex was composed of Factor Xa, Ca2+, and plasma Factor Va plus phospholipid vesicles, or activated platelets in the place of the latter components, similar specific activity values were observed. The combination of Factor Va, Ca2+, and phospholipid enhanced the rate of the Factor Xa-catalyzed activation of prothrombin by a factor of 278,000. Factor Va itself when added to Factor Xa, Ca2+, and phospholipid, enhanced the rate of prothrombin activation by a factor of 13,000. Unactivated Factor V appears to possess 0.27% of the procoagulant activity of thrombin-activated Factor Va. From the kinetics of prothrombinase activity, an interaction between Factor Xa and both Factor V and Factor Va was observed, with apparent 1:1 stoichiometries and dissociation constants of 7.3 x 10(-10) M for Factor Va and 2.7 x 10(-9) M for Factor V. The present data, combined with data on the equilibrium binding of prothrombinase components to phospholipid, indicate that the model prothrombinase described in this paper consists of a phospholipid-bound, stoichiometric complex of Factor Va and Factor Xa, with bound Factor Va serving as the "binding site" for Factor Xa, in concert with its proposed role in platelets.     

Sulfation of Tyr1680 of human blood coagulation factor VIII is essential for the interaction of factor VIII with von Willebrand factor

The acidic region of the Factor VIII light chain was studied with regard to structural requirements for the formation of a functional von Willebrand factor (vWF)-binding site. Factor VIII mutants lacking the B domain, with additional deletions and an amino acid replacement within the sequence 1649-1689 were constructed using site-directed mutagenesis and expressed in Cos-1 cells. These mutants, which were recovered as single-chain molecules with similar specific activities, were compared in their binding to immobilized vWF. Deletion of amino acids 741-1648 or 741-1668 did not affect the binding of Factor VIII to vWF. However, a mutant with a deletion of residues 741-1689 was no longer capable of interacting with vWF. This indicates a role for residues within the sequence 1669-1689 in the formation of a vWF-binding site. When recombinant Factor VIII was expressed in the presence of chlorate, an inhibitor of protein sulfation, the resulting Factor VIII displayed strongly reduced binding to vWF. vWF binding was completely abolished when within the sequence 1669-1689 the tyrosine residue Tyr1680, which is part of a consensus tyrosine sulfation sequence, was replaced by phenylalanine. The Factor VIII sequence 1673-1689 was identified as a high affinity substrate for tyrosylprotein sulfotransferase (Km = 57 microM) in cell-free sulfation studies. It is concluded that sulfation of Tyr1680 is required for the interaction of Factor VIII with vWF. Two synthetic peptides that represent the sequence 1673-1689, but differ with respect to sulfation of Tyr1680 are shown to have vWF binding affinity that is considerably lower than the Factor VIII protein. Several models to accommodate our findings are discussed.     

Regulation of activated protein C by protein S. The role of phospholipid in factor Va inactivation

Protein S enhances the rate of Factor Va inactivation by activated Protein C (Walker, F. J. (1980) J. Biol. Chem. 255, 5521-5524). The activity of protein S is saturable, appearing to interact stoichiometrically with activated Protein C. Diisopropylphosphate-modified activated Protein C reversed the effect of Protein S, further indicating that a Protein S-activated Protein C interaction is required for expression of the activity of Protein S. In the absence of phospholipid, Protein S had no effect on the rate of activated Protein C-catalyzed inactivation of Factor Va. The activity of Protein S was only expressed in the presence of phospholipid vesicles, where it appeared to increase the affinity of the inactivation system for phospholipid. Protein S had no effect upon the rate of Factor Va inactivation in the presence of saturating levels of phospholipid vesicles. The effects of Protein S on the kinetics of Factor Va inactivation corresponded with its effect on the interaction between activated Protein C and phospholipid vesicles, measured by light scattering. In the presence of Protein S, the binding of activated Protein C to phospholipid vesicles was enhanced. Protein S had no effect upon the binding on the zymogen (Protein C to phospholipid vesicles). In conclusion, the stimulatory effect of Protein S on the inactivation of Factor Va by activated Protein C can be attributed, in part, to the enhancement of the binding of activated Protein C to phospholipid vesicles.     

Portal vein thrombosis and high factor VIII in Turner syndrome

BACKGROUNDS/AIMS: Turner syndrome is not usually associated with thrombotic events. The aim of this study is to report 3 Turner syndrome patients with portal vein thrombosis and, in 2 of them, high factor VIII. These findings are compared to values in Turner syndrome patients without thrombosis and controls. METHODS: In different years, 3 patients with Turner syndrome were initially seen at the Gastroenterology Clinic of Hospital de Clínicas de Porto Alegre, Brazil, for portal vein thrombosis. After the most common causes of portal vein thrombosis and thrombophilias had been excluded, the 2 surviving patients were studied for clotting factors VIII, IX and von Willebrand factor. The same factors were also assessed in 25 Turner syndrome patients without thrombosis and 25 normal girls. RESULTS: One of the patients with portal vein thrombosis died before the study. In the 2 surviving patients, factors VIII and von Willebrand levels were >150 IU/dl, which is considered to be high. In Turner syndrome patients without thrombosis, the mean factor VIII level was 127.2 +/- 41.1 IU/dl and for von Willebrand factor 101.2 +/- 26.9 IU/dl, while in control girls these were 116.0 +/- 27.6 and 94.28 +/- 27.5 IU/dl, respectively. Factor VIII and von Willebrand factor were not different between these 2 groups. When non-O blood group Turner syndrome patients and normal girls were compared, the former had significantly higher levels of factor VIII. CONCLUSIONS: This is the first report on the unusual finding of portal thrombosis in patients with Turner syndrome in whom high levels of factor VIII and von Willebrand factor were found. Factor VIII is higher in the non-O blood group Turner syndrome patients without thrombosis when compared to normal girls.     

Reconstitution of human factor VIII from isolated subunits

Human factor VII heterodimers were fractionated into component heavy and light chains using an anti-light chain specific monoclonal antibody immunosorbant. Neither the light chain nor the heavy chain alone possessed activity. Factor VII activity was reconstituted by recombining the subunits in the presence of Mn2+ or Ca2+. Reconstitution of activity also showed ionic strength dependence suggesting the importance of hydrophobic and electrostatic interactions. All factor VIII heavy chains (93 to 210 kDa) recombined with the 83 kDa light chain as judged by retention of all reconstituted heterodimeric forms by the monoclonal immunosorbant. Maximum specific activity (3 units/micrograms) was obtained at a 1:1 molar ratio of light chain:heavy chain. The presence of von Willebrand factor enhanced the rate of factor VIII reconstitution as much as 5-fold. This effect was both ionic strength-dependent and dose-dependent up to a 25-fold weight excess of von Willebrand factor over factor VIII.     

Interaction of the lipid and protein components of pulmonary surfactant Role of phosphatidylglycerol and calcium

We investigated the interaction of a major apolipoprotein of pulmonary surfactant with mixtures of lipids analogous to those found in natural surfactant. The apolipoprotein was extracted from canine surfactant and was purified to about 90% homogeneity. The apolipoprotein was mixed with liposomes of lipids in buffers containing 0.1 M sodium chloride and 3 mM calcium chloride at 22°C for 2 h or 37°C for 30 min. Two fractions were separated by centrifugation in sucrose density gradients at 15 000 rev./min. One was comprised of an aggregated, relatively high density recombinant lipoprotein which sedimented to a position toward the bottom of the centrifuge tube; the other remained at the top of the centrifuge tube and was mainly comprised of unbound lipid. The amount of lipid recovered as a sedimenting lipoprotein was dependent upon its composition. Those mixtures of lipids which contained dipalmitoyl phosphatidylglycerol formed sedimenting complexes which comprised 14% to 53% of the recovered lipid; those without phosphatidylglycerol formed such aggregates with less than 13% of the available lipid. Moreover, the lipid-to-protein stoichiometry of the recombinant was also dependent upon phosphatidylglycerol, and lipids containing this phospholipid displayed enhanced binding at a critical concentration of lipid which varied with temperature and composition. Calcium was required to form the sedimenting complex at 37°C. These results suggest that phosphatidylglycerol may be involved in the formation of a micelle-like complex, the stoichiometry of which is regulated over a narrow range of lipid concentration, and the structure of which involves calcium. The physiological advantage of forming this complex has not been determined. We found, however, that lipids containing phosphatidylglycerol absorbed more rapidly to an air/liquid interface than did those without. This rate of adsorption was further increased after interaction with the apolipoprotein.     

The contribution of Ca2+ and phospholipids to the activation of human blood-coagulation Factor X by activated Factor IX.

The role of the cofactors Ca2+ and phospholipid in the activation of human Factor X by Factor IXa was investigated. By use of a sensitive spectrophotometric Factor Xa assay, it was demonstrated that human Factor IXa can activate Factor X in the absence of cofactors. The presence of Ca2+ as the only cofactor resulted in a 7-fold stimulation of the Factor Xa formation. Kinetic analysis of the Ca2+-stimulated reaction showed that the apparent Km of Factor X was 4.6 microM, whereas the apparent Vmax. for Factor Xa formation was 0.0088 mol of Xa/min per mol of IXa. The presence of phospholipid as the only cofactor had no effect on the rate of Factor Xa formation. However, a several-hundred-fold stimulation was observed when Ca2+ and phospholipid were present in combination. The activation of Factor X in the presence of Ca2+ and phospholipid was found to be kinetically heterogeneous, involving both phospholipid-bound and free reactants. Quantitative data concerning the phospholipid binding of Factors IXa and X were used to study the relation between the rate of Factor Xa formation and the binding of enzyme and substrate to the phospholipid membrane. The results support the hypothesis that phospholipid-bound Factor X is the substrate in the phospholipid-stimulated reaction; however, phospholipid-bound and free Factor IXa seem to be equally efficient in catalysing the activation of phospholipid-bound Factor X.     

Definition of the affinity of binding between human von Willebrand factor and coagulation factor VIII

Factor VIII and von Willebrand factor are two plasma proteins essential for effective hemostasis. In vivo, they form a non-covalent complex whose association appears to be metal ion dependent. However, a precise definition of the nature of the molecular forces governing their association remains to be defined, as does their binding affinity. In this paper we have determined the dissociation constant and stoichiometry for Factor VIII binding to immobilized von Willebrand factor. The data demonstrate that these proteins interact saturably and with relatively high affinity. Computer assisted analyses of the Scatchard data favour a two site binding model. The higher affinity site was found to have a Kd of 62 (+/- 13) x 10(-12) M while that of the lower affinity site was 380 (+/- 92) x 10(-12) M. The density of Factor VIII binding sites (Bmax) present on von Willebrand factor was 31 (+/- 3) pM for the high affinity binding site and 46 (+/- 6) pM for the lower site, corresponding to a calculated Factor VIII: von Willebrand factor binding ratio of 1:33 and 1:23, respectively.